US2024132A - Process for introducing steel-forming additions into the aluminogenetic iron in aluminothermal welding - Google Patents

Description

Dec. 10, 1935. I w. SANDER 2 PROCESS FOR INTRODUCING STEEL FORMING ADDITIONS INTO THE ALUMINOGENETIC IRON IN ALUMINOTHERMAL WELDING Filed June 30, 1934 12 1 V PRIMER R01 CO ER ALL OYING ING EDIEN IS SILICON CARBIDE mxsp WITH 7 sum-FO MING. MHTERIALS J O 1 ON LATE R F 1 1%? HOLE 5 i, A CfiU clan:

\\ CRUCIBLE V :HLUMINO rmzxmc MIXTURE :HLLOYING CONSTLTUENTS MIXED f wm suns FORMING s05 S'IBNCES m 2 J ASBESTO Pacnma q. 4 THPHOLE 3M hZZ/ze/m scuzolel;

TAPPINC; R09

PRGCESS FQR HNTBODUG STE roume ADDKTIGNS Q AILU- oGENE'rIo rush ma Willie Sander, Essen 'mrTh. Goldso isnor to the :a.

-on-thc-R,

Application June 39, 1934 I In m m;

This invention relates to a process for introducinc"v steel-forming additions or alloying constituents into the aluminogenetlc iron in aluminothermal welding. I

it is known to introduce steel-forming addi-' tions such as manganese, silicon, carbon, silicon carbide and the like, into the aluminogenetic iron in eluminothermal welding, by adding these substances-either as such, or alloyed with one another or with iron-4:0 the aluminothermal mixture prior to the reaction or to the melt after the reaction is completed and before tapping.

This process, however, was attended with the drawback that the steel-forming substances took part, to some extent in the aluminothermal reaction, by reacting with the oxygen of the iron oxide, so that not inconsiderable quantities passed into the slag and were thereby lost as regards the formation of alloys. it has also been proposed to dispose the steel-termite, substances, in the form or fine grains on the bottom of the reaction crucible, an arrangement that resulted in a more complete and uniform alloying of said substances with the iron. With this method of introduction the steel-forming substances can serve at the same time for sealing the tap hole oi the crucible. Moreover, processes are also hnorwo, especially in connection with the employment or silicon carbides, for designing of the crucibles without manual tapping facilities whereby, after the silicon carbide (which serves time for sealing the tap-hole) has be u otissoived in the aluminogenetically produced n, the reaction product is intended to run out or the crucible automatically or spontaneously,

at the prescribed time. These processes, howev r are attended with considerable defects, on particularly serious, especially when the silicon carbide, which is highly effective for the iorroetion or the steel, is employed.

As is known, coercial silicon carbide conmetallic oxide is burned to carbon monoxide] causes the reaction to proceed in a very violent manner which, on the one hand may scatter the molten reaction product out of the crucible and, on the other, may cause the reaction product to run prematurely out of the cruciisle owing to the silicon carbidein the bottom being set in vortical motion.

it has now been found that the desired cunts N AL -on-the-Ruhr do No. treats ctr of we. additions-such as silicon and carbon when silicon carbide is employed-can be introduced into the alcgenetic iron without the occurrence of the aforesaid J1 rwbachs, if the steel-forming addition (such. as silicon carbide) is d mixed with a quantity (suitable for the special circumstances of each case) of an inert substance of high melting point and said mixture be used at the same time for sealing the tap hole of the crucible.

Such inert substances comprise, for example, alumina, blast-furnace slag and, in particular, slags food in the alumlnothermal reaction. Owing to their high melting point, these sub= stances, in ature with the steeldorming adl ditions, form a, reliable seal and, moreover, moderate the course oi the reaction during the dissolving of the steel-tow: additions in the aluminogenetic iron.

This process has rendered it possible, for the first time, to ensure in a perfectly reliable n-= nor, that the reaction product will run out oi tapless crucibles at the desiredmoment. In addi= tion to the inert refractory substances, other al loying constituents such as manganese, nickel, ,25 chromium, titanium, vanadium, tungsten and the like my be added to the silicon carbide. Alter natively, the mixture or silicon carbide and inert substances may be employed alone as sealins materiel whilst the other steel formers may to be strewn in larger grain sizeover said seal.

The choice of the components and their amount depends substantially on the amount or the aluogenetic mixture to which they are to be added, and also on the desired composition of the aluminogenetic iron. cibies with and without tapping devices may be used. ii, for example,

crucibles with tapping devices be employed, a

mixture of about two-thirds silicon carbide and one-third aluminothermal slag, such as is obtained in the alumin'othermal production oi. manganese, has been found suitable.

' In the accompanying drawing I have shown how my invention may be used in coercial practice in connection with crucibles which are conventional in the art. in this showing Fig. l is a vertical section of a ss=csilcd taoless crucible, previously described in. i No. 561,364, while,

Fig. 2 is a corresponding section oi a crucible 54? provided with tapping rod, this crucible being shown previously in German Patent No. Meet? In the figures like elements are designated by like reference numerals. Element i represents the crucible itself, which is provided with a tap 55 hole 2. The tap rod 3 of the crucible of Fig. 2 is shown at the bottom oi the figure, this rod being provided at its top with an iron plate t which normally is retained by the constricted bottomof the crucible. Above this iron plate 3 there may be placed a layer of asbestos packing 5 which prevents melting of the iron plateprior to tapping. The alloying ingredients, which are mixed with the slag-forming substances in accordance with the present invention, are shown disposed as a layer 8 above the asbestos packing. An iron plate 6 may be placed on top of the mixture of alloying ingredients and slag-forming materials, and this is surmounted by the usual alumino-thermic mixture '1.

In the operation of the crucible shown in Fig. 2, the alumino-thermic mixture is first ignited. The material above the iron plate 5 soon becomes molten and the heat then melts this plate. This exposes the mixture of alloying ingredients and slag-forming substances to the action of the molten' alumino-thermic mixture. The slag-forming materials present in this mixture slow down the reaction between the alloyingingredients and the melt, producing a smooth reaction and preventing sputtering. These materials also serve to protect the iron plate 4 and the asbestos packing 5 to somev extent from the high heat developed during the alumino-thermic reaction. The presence of these substances thus insures retention of the melt in the crucible until the latter is positively tapped by raising the tap rod 3.

The tapless crucible shown in Fig. 1 has a quite similar structure. In this crucible the tap hole 2 is closed by a thin iron plate 13. This is covered by a mixture 8 of silicon carbide and slagi'orming constituents, this mixture forming a packing or sealing layer above the tap hole. This mixture is covered by a layer 9 of alloying ingredients which in turn is surmounted by the alumino-thermic mixture 1. The crucible is shown furnished with a primer iii and primer rod II. It is also provided with a cover ii.

The operation of the crucible shown in Fig. 1 proceeds as follows: The primer i0 is used to ignite the alumino-thermic mixture which rapidly becomes molten, melting and uniting with the alloying ingredients 9. This exposes the mixtlne 8 of silicon carbide and slag-forming ingredients to the action of the alumino-thermic mixture. The silicon carbide reacts with the oxide of the alumino-thermic mixture to some extent forming carbon monoxide. But the pres ence of the slag-forming materials slows down this reaction and prevents the usual sputtering. The mixture of silicon carbide and slag-forming substances thus unites with the melt slowly and smoothly and this is not completed until the entire mass of alumino-thermic mixture has had time to become molten and homogenized, that is, until the alumino-thermic reaction has been completed. At this point the iron plate i3 becomes exposed to the melt andthis plate dissolves and the crucible is automatically tapped at the proper instant. The time of tapping may be controlled, as described previously, by the addition of the proper amount of slag-forming materials. The greater the amount of slag-forming materials added to layer 8 the longer the delay before the crucible is automatically tapped. This means that the time of tapping may be predetermined, a result which was impossible prior to the present invention.

Various changes may be made in the details of construction of the crucibles'and the manner of applying the mixture of alloying ingredients and slag-forming materials as a packing without departing from the purview of the present invention. Various changes which fall within the scope of the following claims will be 24; once evident to those skilled in the art.

What I claim is: V

1. In the alumino-thermic process wherein various alloying constituents are added to the alumino-thermic mixture in a crucible, the improvement which comprises mixing such alloying constituents with inert, refractory, slag-forming substances, applying said mixture as a packing layer about the tap hole of said crucible to prevent flow of the alumino-thermic melt prior to completion of the alumino-thermic reaction and adding the usual alumino-thermic mixture to said crucible above said packing layer.

2. In the alumino-thermic process wherein alloying constituents are employed as a packing to cover the tap hole of the reaction crucible, the improvement which comprises mixing such alloying constituents in finely granular form with inert, finely divided substances oi high melting point and applying this mixture as a packing layer over said tap hole, thereby sealing said tap hole and preventing flow of the alumino-thermic melt prior to completion of the alumino-thermic reaction.

3. The process of claim 2 wherein the inert, lsiligh-melting substances are alumino-thermic 98S. 4. The process of claim 2 wherein a mixture of silicon carbide and inert, high melting substances is applied as said packing layer.

5. In the alumino-thermic process wherein alloying constituents are employed as a packing to cover the tap hole of the reaction crucible, the improvement which comprises mixing such alloying constituents in finely granular form with finely divided inert, refractory substances of high melting point, applying this mixture as a sealing layer over said tap hole and placing a layer of alloying constituents above said sealing layer thereby sealing said tap hole and preventing flow oi the alumino-thermic melt prior to completion of the alumino-thermic reaction.

6. In the alumino-thermic process wherein alloying constituents are employed as a packing to cover the tape hole of the reaction crucible, the improvement which comprises applying as a sealing layer above the tap hole of a reaction crucible a mixture of silicon carbide and high melting inert refractory material of such depth and in such proportions as to seal said tap hole until the alumino-thermic reaction has been completed and then to react with the resulting aluminuthermic melt, thereby breaking said seal and automatically tapping said crucible.

SANDER.

Images